Singularities of Rational Plane Quartics

David A. Cox

Department of Mathematics Amherst College [email protected]

Barcelona June, 2012

David A. Cox (Amherst College) Singularities of Rational Quartics BarcelonaJune,2012 1/10 Outline

Joint work with Andy Kustin, Claudia Polini and Bernd Ulrich

Goal Study the singularities of rational plane quartics using the methods of commutative algebra

Computer: Describe the singularities and give the strategy Blackboard: Give some of the details

Full details appear in Sections 8 and 9 of A Study of Singularities on Rational Curves via Syzygies.

David A. Cox (Amherst College) Singularities of Rational Quartics BarcelonaJune,2012 2/10 Singular Points of Rational Quartics

For an irreducible rational quartic in P2, there are nine possible singular points:

Name Name Mult:∞-near;Branches

node A1 2;2 cusp A2 2;1 tacnode A3 2:2;2 ramphoid cusp A4 2:2;1 oscnode A5 2:2:2;2 A6-cusp A6 2:2:2;1 ord triple pt D4 3;3 tacnode-cusp D5 3;2 mult-3 cusp E6 3;1

David A. Cox (Amherst College) Singularities of Rational Quartics BarcelonaJune,2012 3/10 Configurations of Singular Points

For an irreducible rational quartic in P2, there are 13 possible configurations of singular points: 3 with µ = 1: 1 ordinary triple point 1 tacnode-cusp 1 multiplicity-3 cusp

10 with µ = 2: 4 with i nodes and j cusps, i + j = 3 2 with one tacnode plus one node or cusp 2 with a ramphoid cusp plus one node or cusp 1 oscnode

1 A6-cusp

David A. Cox (Amherst College) Singularities of Rational Quartics BarcelonaJune,2012 4/10 Two Pictures

Threenodes Tacnodeandnode

David A. Cox (Amherst College) Singularities of Rational Quartics BarcelonaJune,2012 5/10 Two More Pictures

Oscnode Tacnode-cusp

David A. Cox (Amherst College) Singularities of Rational Quartics BarcelonaJune,2012 6/10 Organize the Configurations

We focus on the 10 configurations with = 2. A Coarse Stratification We organize these configurations as follows: 3 nodes (6 branches) 2 nodes and 1 cusp (5 branches) • S2,2,2:  1 node and 2 cusps (4 branches) 3 cusps (3 branches)  1 tacnode and 1 node (4 branches) 1 tacnode and 1 cusp (3 branches) • S2:2,2:  1 ramphoid cusp and 1 node (3 branches) 1 ramphoid cusp and 1 cusp (2 branches)  1 oscnode (2 branches) • S2:2:2: 1 A6-cusp (1 branch)

The notation S2,2,2, S2:2,2, S2:2:2 is from my second lecture.

David A. Cox (Amherst College) Singularities of Rational Quartics BarcelonaJune,2012 7/10 Count Branches

To count branches, we use the following:

Theorem (CKPU) Let (a, b, c) give a parametrization P1 →C⊆ P2 and set

∂a ∂b ∂c ∂s ∂s ∂s  N = . ∂a ∂b ∂c      ∂t ∂t ∂t 

If sP is the number of branches at P, then

deggcd I2(N)= mP − sP . P

If we know the multiplicities, this gives the number of branches.

David A. Cox (Amherst College) Singularities of Rational Quartics BarcelonaJune,2012 8/10 Strategy

Three Steps Step 1: Stratify using the number of visible singular points (S2,2,2, S2:2,2, S2:2:2). Step 2: Refine the stratification using the number of branches.

Step 3: Curves with 1 tacnode and 1 cusp and with 1 ramphoid cusp and 1 node both have two visible singular points and three total branches. Separate these using the conductor.

David A. Cox (Amherst College) Singularities of Rational Quartics BarcelonaJune,2012 9/10 Strategy

Three Steps Step 1: Stratify using the number of visible singular points (S2,2,2, S2:2,2, S2:2:2). Step 2: Refine the stratification using the number of branches.

Step 3: Curves with 1 tacnode and 1 cusp and with 1 ramphoid cusp and 1 node both have two visible singular points and three total branches. Separate these using the conductor.

David A. Cox (Amherst College) Singularities of Rational Quartics BarcelonaJune,2012 9/10 Strategy

Three Steps Step 1: Stratify using the number of visible singular points (S2,2,2, S2:2,2, S2:2:2). Step 2: Refine the stratification using the number of branches.

Step 3: Curves with 1 tacnode and 1 cusp and with 1 ramphoid cusp and 1 node both have two visible singular points and three total branches. Separate these using the conductor.

David A. Cox (Amherst College) Singularities of Rational Quartics BarcelonaJune,2012 9/10 Strategy

Three Steps Step 1: Stratify using the number of visible singular points (S2,2,2, S2:2,2, S2:2:2). Step 2: Refine the stratification using the number of branches.

Step 3: Curves with 1 tacnode and 1 cusp and with 1 ramphoid cusp and 1 node both have two visible singular points and three total branches. Separate these using the conductor.

David A. Cox (Amherst College) Singularities of Rational Quartics BarcelonaJune,2012 9/10 The Conductor

Let (a, b, c) of degree d parametrize C ⊆ P2, and let (d) ∞ B = ℓ=0Bℓd ⊆ B = k[s, t] be the dth Veronese subring. Then c = {r ∈ k[a, b, c] | r B(d) ⊆ k[a, b, c]} is the conductor of k[a, b, c] ⊆ B(d).

Theorem 1 (General d) cB = F(s, t)s, td−2, where deg F = (d − 1)(d − 2).

Theorem 2 (d = 4) 2 2 2 1 tacnode and 1 cusp ⇒ F = ℓ1ℓ2ℓ3. 4 1 ramphoid cusp and 1 node ⇒ F = ℓ1ℓ2ℓ3.

David A. Cox (Amherst College) Singularities of Rational Quartics BarcelonaJune,2012 10/10 The Conductor

Let (a, b, c) of degree d parametrize C ⊆ P2, and let (d) ∞ B = ℓ=0Bℓd ⊆ B = k[s, t] be the dth Veronese subring. Then c = {r ∈ k[a, b, c] | r B(d) ⊆ k[a, b, c]} is the conductor of k[a, b, c] ⊆ B(d).

Theorem 1 (General d) cB = F(s, t)s, td−2, where deg F = (d − 1)(d − 2).

Theorem 2 (d = 4) 2 2 2 1 tacnode and 1 cusp ⇒ F = ℓ1ℓ2ℓ3. 4 1 ramphoid cusp and 1 node ⇒ F = ℓ1ℓ2ℓ3.

David A. Cox (Amherst College) Singularities of Rational Quartics BarcelonaJune,2012 10/10